Sensors are designed to detect medium-to-large animals weighing upwards of 3 kg (photo: researcher's archive)

Startup develops animal detection system to prevent roadkill
2017-08-30

Sensors are designed to detect medium-to-large animals weighing upwards of 3 kg.

Startup develops animal detection system to prevent roadkill

Sensors are designed to detect medium-to-large animals weighing upwards of 3 kg.

2017-08-30

Sensors are designed to detect medium-to-large animals weighing upwards of 3 kg (photo: researcher's archive)

 

FAPESP Research for Innovation – When biologist Fernanda Delborgo Abra began her master’s course in ecology at the University of São Paulo’s Bioscience Institute (IB-USP) in Brazil, she knew she wanted to focus on the problem of wildlife – vehicle collisions, or roadkill, and what can be done to mitigate it. This concern led her to set up ViaFauna, a road mitigation firm, with two partners, Mariane Rodrigues Biz Silva and Paula Ribeiro Prist. The firm is developing Brazil’s first ever electronic roadside animal detection system.

Passa-Bicho, a prototype produced by ViaFauna with support from FAPESP’s Innovative Research in Small Business (PIPE) program, is designed to mitigate the impact of roads on wildlife and increase road user safety by reducing wildlife-vehicle collisions. More than 23,000 road accidents involving users and animals were recorded in São Paulo State alone between 2005 and 2013.

The collisions often involve endangered species such as the tapir (Tapirus terrestris), maned wolf (Chrysocyon brachyurus) and jaguar (Panthera onca), although domestic animals such as horses, cattle and dogs are just as likely to be victims. In addition to the environmental damage the collisions cause, they put the lives of road users at risk and may oblige road operators to disburse costly compensation. 

Wild and domestic animals of medium-to-large size (over 3 kg) are targeted by ViaFauna’s detection system because of their detectability and impact on road safety. The system comprises a pair of motion sensors (transmitter and receiver) affixed to short poles similar to those used for speed traps and installed 100 m apart. “Each pair of sensors covers a roadkill hotspot,” Abra explains.

The transmitter sends the receiver a beam of infrared light, which is invisible to humans and other vertebrates. When the beam is interrupted by an animal, the sensor sends a signal to the pole, which in turn transmits the information via radio, activating an electronic message panel or, in a simpler version, a revolving beacon light on top of an animal crossing sign. 

“This system is far more effective than a mere sign warning that wildlife may cross the road,” Abra says. “When drivers see static warning signs, they never know when animals will actually cross, and so they tend not to pay too much attention. Our detection system warns drivers hundreds of meters or even a kilometer or two ahead of an actual animal crossing, giving them time to take precautions. The scientific literature shows animal detection systems can reduce the number of collisions by as much as 90%.”

More sophisticated systems used in the United States include thermal imaging cameras and recognition software capable of “decision making”, she explains, registering every animal that crosses the road but warning road users only when the animal is a safety hazard.

Based on its research, ViaFauna preferred a simpler system of the kind widely used in European countries. Moreover, studies performed during Stage 1 of the PIPE project between June 2016 and April 2017 indicated the need to change the initial goals. “The original idea was that Passa-Bicho would emit visible light to help users see an animal as it crossed the road,” Abra recalls. “Our studies led us to abandon this concept because a floodlight would attract insects and their predators, and even scare some wildlife species away.”

Stage 1 of the project enabled the firm to develop a functional prototype powered by solar panels and including data loggers. “Currently, researchers only know how many animals are killed on a road. Our system will show how many cross the road successfully, contributing to studies of animal movement dynamics,” Abra says.

The next step will be to test the prototype at the University of São Paulo’s Luiz de Queiroz College of Agriculture (ESALQ-USP) and see how it withstands weathering. “We also need to make several changes to the prototype to make its design appear more ‘market-friendly’,” Abra explains.

Multidisciplinarity

During PIPE Stage 1, Abra collaborated with researcher Katia Maria Paschoaletto Micchi de Barros Ferraz, a professor at ESALQ, and Marcel Huijser, an expert on wildlife roadkill mitigation measures at the University of Montana in the US. Both jointly supervised her master’s research. 

While the project was in progress, Abra realized the need to add other professionals and knowledge areas to her field of study, starting with entrepreneurship. Learning to interact with the business world has perhaps been her greatest challenge. “The first hurdle I had to surmount was internalizing the responsibility of being an entrepreneurial researcher,” she says. “Until then, I’d only ever thought of myself as doing pure research.”

When she began her master’s course, Abra was unaware of the existence of the Center for Innovation, Entrepreneurship & Technology (CIETEC), the incubator that was to provide initial support for ViaFauna. “Undergraduate courses in hard sciences fail to discuss anything linked to business,” she says. She was introduced to PIPE at CIETEC and given advice on preparing her project for submission to the program, which required several features that made it quite different from the academic projects she was accustomed to. 

Later on, still during Stage 1, ViaFauna was selected to participate in the Third Training Program for High-Tech Entrepreneurs offered by PIPE. “The program took us to see several environmental and transportation agencies to help us make sure our projects took market needs into account,” Abra explains.

An even stronger impression was made on her by the Leaders in Innovation Fellowships (LIF) training program held in London (UK) between November 28 and December 9, 2016, by the Royal Academy of Engineering (RAEng). Abra and others were able to take the course thanks to a partnership between the RAEng and FAPESP. The two-week program consisted of intensive courses in business management, financial planning, patenting, marketing and publicity, among other topics relating to leadership, innovation and entrepreneurship. “PIPE makes you aware of the importance of knowing other sciences required for project development,” Abra says.

Since Stage 1, Abra has pursued the information she needs to enable her to dialogue with the experts in electronics responsible for making the system work as she conceived it. For Stage 2, the team will be even more multidisciplinary as ViaFauna is joined by Trapa Câmera, a firm that specializes in wildlife camera traps and other environmental monitoring devices, and Hoobox Robotic, a robotics and artificial intelligence startup also supported by PIPE. Both firms will participate in tests of ViaFauna’s prototype. “Today’s professionals have to be multidisciplinary. You can’t stay within the confines of your initial training,” Abra says.

ViaFauna Consultoria Ambiental
Site: viafauna.com.br
Address: R. Delmira Ferreira, 312, São Paulo (SP), 04125-120, Brazil
Tel: +55 11 98331 2228
Email: viafauna@viafauna.com 

 

  Republish
 

Republish

The Agency FAPESP licenses news via Creative Commons (CC-BY-NC-ND) so that they can be republished free of charge and in a simple way by other digital or printed vehicles. Agência FAPESP must be credited as the source of the content being republished and the name of the reporter (if any) must be attributed. Using the HMTL button below allows compliance with these rules, detailed in Digital Republishing Policy FAPESP.